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TJ 1400 .F77
REPORT NO. UMTA IT-06-0126-78-2
ACCELERATING MOVING WALKWAY SYSTEMS
Technology Assessment
Engineering Research and Development Division 1HE PORI AUIIIORIIY®!Jl ~@[Rlb!J
One World Trade Center New York, N.Y. 10048
Report B / April, 1978
FINAL REPORT Document is available to the U.S. public through the
National Technical Information Service, Springfield, Virginia 22161.
Prepared for
U.S. DEPARTMENT OF TRANSPORTATION Urban Mass Transportation Administration
Office of Technology Development and Deployment Washington, D.C. 20590
This document is disseminated under the sponsorship of the U.S. Department of Transportation in the interest of information exchange. The United States Government assumes no liability for its contents or use thereof. The United States Government does not endorse products or manufacturers. Trade of manufacturers' names appear herein solely because they are considered essential to the object of this report.
Technical keport Documentation Poge
1. Report No. 2. Government Accessir 1' No. 3. Recipient's Catalog No.
UMTA-IT-06-0126-78-2 4. Title and Subtitle
Accelerating Moving Walkway Systems Technology Assessment (Report B of Series)
5. R Oa
____ March 1978 :'--'-":--'-=-'--'~=----- --- ----.. 6. Perlorm,ng o;goni zolion Code
--~r:_L Authority of NY & -~ i----::----:--;-:------------------------l 8. Perlorm,ng Orgonizolion Report No.
7. Author/ s)
Fruin, J., Marshall, R., Zeigen, M. 9, Performing Orgoni zotion Nome and Address
Port Authority of New York and New Jersey One World Trade Center New York, New York 10048
Ji), Work Unit No.
11. Controct or Grant No.
No. IT -06-0126 I
i--------------·-------------...J 13. Type of Report and Perice.I Covered 12. Sponsoring Agency Name and Address
U. S. Department of Transportation Urban Mass Transportation Administration
t-
__ 4o_o_s_e_v_e_n_th_S_t_r_e_e_t_,_s _. _w_. _____________ ___,__1_4._Sp-on-soring Agency Code -~ Washington, D. C. 20590 _
l 5. Supplementary Notes
t-:-16:--.-A:-:-b-,t-,o-ct ___________________________________ _
Variable speed, Accelerating Moving Walkway Systems (AMWSs) represent the next evolutionary phase in a century of IOOVing way transportation system development. AMWS(s} resemble conventional constant speed moving walks in appearance, but have the capability through changing treadway configuration to accelerate pedestrians to 4 to 5 times the ·conventional system speed. An assessment of the current state of AMWS technology indicates that there are five systems at various stages of hardware development and testing. Two systems are bi-directional loops using a treadway of intermeshing pallets. The remaining systems are one directional using treadways comprised of either laterally IOOVing pallets, intermeshing leaves, or abutting rollers. Handrails are developed for only two systems, one employing multiple conventional handrails in series, and the other utilizing IOOving variable speed handgrips. Site adaptability of the systems varies with the system width and sub-grade depth installation envelope, as well as horizontal and vertical alignment adaptability. Furnishing and installation costs of the systems are relatively high, but their mechanical simplicity results in comparatively low operating expenses and energy use. A review of AMWS safety and human factors indicates, apriori, no significant reason why the systems cannot operate at levels of safety acceptable to the public, providing a specific safety program is followed.
17. Key Words
Accelerating Moving Walkways, Technology Assessment, Moving Way Transit, Pedestrians, Passenger Conveyors
18. Distribution Statement
Available to the Public through the National Technical Information Service Springfield, Virginia 22161 •
19. Security Classi I. (of !his report) 20. Security Classif. (of this page) 21. No, of Pages 22. Price
Unclassified Unclassified
Form OOT F 1700.7 (8-72) Reproduction of completed poge outhori :r.ed
TABLE OF CONTENTS
LIST OF ILLUSTRATIONS
UST OF TABLES
SUMMARY
1.0 MOVING WAY TRANSPORTATION SYSTEM DEVELOPMENT
1.1 Moving Way Transportation System Classifications
1.2 History of Moving Way Transportation Systems
1.3 The Modern Escalator
1.4 Manufacturers• Survey
2.0 DESCRIPTIONS OF CANDIDATE SYSTEMS
2 .1 The Dunlop Speedaway System
2.2 RATP TRAX System
2.3 Applied Physics Laboartory (APL) System
2.4 The Boeing System
2.5 Dean Research Corporation System
3.0 SUMMARIES OF SYSTEM CHARACTERISTICS
3.1 Siting Characteristics
3.2 Passenger Service Characteristics
3.3 AMWS Costs
3.4 Developer Qualifications
3.5 Safety and Human Factors
APPENDIX
REFERENCED BIBLIOGRAPHY
CHRONOLOGICAL HIGHLIGHTS
i
PAGE
ii
iii
iv
1
4
12
24
27
28
29
35
41
47
49
51
52
57
61
64
67
A-1
A-3
LIST OF ILLUSTRATIONS
PAGE
FIGURE 1 .1 - RENO ESCALATOR 17
FIGURE 1.2 - 1939 WORLD'S FAIR 20
FIGURE 1.3 - A TYPICAL ESCALATOR 25
FIGURE 2 .1 - DUNLOP SPEEDAWAY 30
FIGURE 2.2 - DUNLOP SPEEDAWAY 32
FIGURE 2. 3 - DUNLOP SPEEDAWAY 33
FIGURE 2.4 - DUNLOP SPEEDAWAY 34
FIGURE 2 .5 - RATP TRAX 36
FIGURE 2.6 - RATP TRAX 37
FIGURE 2. 7 - RATP TRAX 38
FIGURE 2.8 - RATP TRAX 39
FIGURE 2.9 - APL 42
FIGURE 2.10 - APL 43
FIGURE 2.11 - APL 44
FIGURE 2.12 - APL 45
FIGURE 2.13 - BOEING 48
FIGURE 2.14 - DEAN 50
FIGURE 3. l - PLAN VIEWS CANDIDATE AMWSs 53
FIGURE 3.2 - SECTION VIEWS CANDIDATE AMWSs 54
H
LIST Of TABLES
TABLE A - TECHNOLOGY ASSESSMENT - COMPARATIVE SUMMARY
TABLE 1.1 - AMWS CLASSIFICATIONS
TABLE 3. l - SITING CHARACTERISTICS
TABLE 3.2 - PASSENGER SERVICE CHARACTERISTICS
TABLE 3.3 - PRELIMINARY COST DATA
TABLE 3.4 - AMWS EQUIPMENT HAZARD SUMMARY
iii
PAGE
Vii
6
55
60
63
72
summary A rev1ew of the available v~r1able speed ~ccelerating moving
walkw~y system (AMWS) technology for the purpose of determtning candi
dates for a public use demonstration indicates that there are currently
five potential AMWS developers at, or near, the hardware prototype stage
of development and testing. These five systems, 1n the approximate
order of their development stage include: (1) the Speedaway system by
Dunlop, (2) the TRAX system by the Regie Autonome de Transports Par1siens
(RATP - Paris Transit Authority), (3) the Applied Physics Laboratory {APL)
system by Johns Hopkins University, (4) the Boeing system by the Boeing
Corporation, and (5) the Dean system by the Dean Research Corporation.
This report contains a general review of moving way transpor
tation system technology development history, as well as an assessment
of the five AMWSs listed above from the standpoints of (l} siting char
acteristics, (2) passenger service characteristics, (3) costs, (4) de
veloper qualifications, and (5) system safety and human factors. The
systems considered in the report vary in their dimensional envelopes,
thus affecting their adaptability to site conditions which might typi
cally be encountered in urban applications. Two of the systems are bi
directional, limiting their applications to locations where there is this
type of traffic requirement as well as sufficient width. The three re
maining systems are uni-directional but vary in alignment and sub-grade
depth requirements. The performance of the various systems will depend
on their dimensions, motion characteristics of treadway and handrails,
and treadway and handrail materials and configuration. Initial user
iv
tests show generally favorable acceptance of the available prototypes,
but some performance modifications may be necessary to meet the require
ments of an unlimited public use demonstration. Accelerating moving
walkways are continuous service systems generally offering more favor
ab1e passenger service levels than vehicular transit for shorter dis
tance applications.
Accelerating Moving Walkway System costs for fabrication and
installation of initial production units are expected to be in the ap
proximate range of about 50 to 100 per cent greater than conventional
moving walkway systems, or about $1500 to $2400 per lineal foot $4920-
$7870/m). Additional costs would be required for structural, architec
tural, and electrical system preparation of the site, and would vary
significantly for at grade, or grade separated installations. Accel
erating walkways are expected to require relatively little additional
manpower for mechanical maintenance than conventional escalators and
moving walks, and except for the premium for increased speed, operation
and maintenance costs are expected to be consistent with the conventional
systems.
The qualifications of the various developers to manufacture
and install an AMWS unit for a public use demonstration, as well as to
provide all the necessary logistic support for a demonstration, varies
from well established manufacturers of moving way equipment to those
with very limited experience in this field. However, it 1s expected
that these deficiencies could be remedied through licensing arrangements
and through the support of qualified consultants where necessary. A re
view of the safety and user human factors related to the available
V
accelerat1ng walkway prototypes and system components has established
no Qpparent reason, apriori, why these systems cannot be operated at
levels of safety acceptable to the publtc, but this assumes that a
basic safety program 1s followed not only addressing equipment design,
but instruction of passengers in the proper use of the system. A com
parative sunmary outline of the system assessments follows in Table A.
vi
:s.
~CCELERATING MOVING WALKWAY SYSTEMS
-ECHNOLOGY ASSESSME~T - COMPARATIVE SUMMARY TABLE A
·--...
!TEil MODEL ::JUNLOP SPEEDAWAY
' I
RATP TR!',X
1. Sys tern Type and Current Status
One-directional, abutting i Two directional loop, inter-pailet treadway; fully tested! meshing pallet treadways; prototype, near production. 1 partially tested full scale
2. Siting Characteristics "S" shaped al i wide ends, 57 level sites.
30 ft,
' prototype.
i Linear 14-16 ft. width i throughout, 7.4 ft. subgrade 'at ends, 20 in. on line, , some grade and alignment i variability. I
3.1• Passenger Service Characteristics (all ! systems continuous)
Motions treadway and handrail Motions treadway acceptable should be acceptable to based on tests, handrail public based on tests, undergoing tests.
4. I Estimated Total Costs (Equipment, Site Construction and Installation) per lineal foot or route installed, based on grade '$34 74/LF
5.
6.
1000 ft; bridge 1$4194/LF
subway $5864/LF
Developer Qualifications
Safety and Human Factors Potential Prob 1 em Areas
I
Fully qualified moving way system manufacturer.
JHandrail proximity at wide 'entrance and exit, multiple
!handrails, pallet movement beneath balustrade.
I
I I I
$4430/LF
i$7020/LF
lu.s. licensee, possible confsultant assistance required.
I I
!Bunching, treadway \handrail synchronicity •,;i
l·treadway, handrail detailing under test.
:GHNS HOPKl~S ~.P, . i:OE!NG iJ£AN RESEARCH
---------- -~- -·-·--- - --· ·--
· One directional, intermeshing· Two directional loop, inter- One directional, abutting ieaf treadway, partially meshing leaf treadway, re- roller treadway, prototype tested, reduced scale proto-' auced scale prototype under segment partially tested. type. construction.
near, 6 ft. approx. width throughout, 15-24 in. subgrade, some grade and alignment variability.
Motions treadway acceptable based on tests, nandrail designed but not tested
$2560/LF
$3440/LF
,~4530/LF '
licensee, possible contant assistance required.
Bunching, treadway meshing, handrail not tested.
-----··- ·---'--------------, linear, 14 ft. width
throughout, above grade installation, some grade and alignment variability.
Installation envelope not defined, linear, 6 ft. approx. width, promising grade and alignment variability.
No testing ctt time of reportJ Treadway motions reported as 1 acceptable based on limited
tests.
$3030/LF
$4250/LF
$5620/LF
$2'160/LF
$37 40/LF
$4830/LF
Qua 1 ifi ed transportation j Industrial conveyor manufac-sys tem manufacturer, possibl~ turer, possible consultant consultant assistance re- · assistance required, moving quired, moving way passenger I way passenger systems. systems.
Bunching, treadway meshing, Treadway rippling, v1brat1on handrail detailing not known and other affects, handrail or tested. detailing not known or
· tested.
1.0 MOVING WAY TRANSPORTATION SYSTEM DEVELOPMENT
Accelerating, variable speed irechanical moving walkways
represent the next phase of development in the century of evolution
of moving way system technology. Conventional single speed mechanical
walkways have been installed in many airports, transit systems, and
other urban activity centers, for the purpose of extending the effective
trip range of the pedestrian. Improved pedestrian transportation is a
widely recognized urban development objective which is considered to have
significant societal benefits which are identified in more detail in
Report D of the Demonstration Project study series, Accelerating Moving
Walkway Systems -- Market, Attributes, Applications, Benefits. In
creasing the number of pedestrian trips and pedestrian trip distances
would reduce the atmospheric, noise, and visual pollution caused by
vehicular transportation, and improve the effectiveness and economic
utility or urban core areas and activity centers.
The current conventional moving walkway technology speed
limitations dictated by the requirements for a safe and comfortable human
boarding and exit speed are an inherent constraint which has limited
the application of these systems to horizontal movement problems in
trip ranges encountered in many urban centers. System speeds are
about half normal walking speeds and the concomitant trip time
penalty for riders who choose to stand, rather than walk on the
systems, has resulted in commonly accepted maximum system lengths of
about 600 feet (183 M.). The objective of Accelerating Moving
Walkway System (AMWS) technology development is to produce a system
which will operate with a line speed about twice the speed of walking,
providing a time and human energy saving advantage which will extend
- 1 -
the effective moving way system range, increasing the applicability to
pedestrian movement problems and potentially competing with certain
types of vehicular transit systems for short range applications.
Boarding and exiting speeds for variable speed systems would be the
same as conventional escalator and moving walks. The continuous ser
vice no waiting aspect of moving way transit systems produces travel
time advantages for short trips over vehicular systems with batch load
ing and operating on typical headways.
The purpose of this Technology Assessment report is to deter
mine the current status of development of AMWS technology, to establish
potential candidates for a public demonstration, to establish definitive
cost and operational data, as well as user acceptability and safety.
AMWS{s) are currently in all stages of development ranging from theo
retical concepts which have not been translated into any form of mechan
ical design, to systems that have been advanced to prototype hardware
limited to experimental use, or in two cases, to full scale near pro
duction models. The complete design details and possible design re
visions of all systems are not yet known, limiting the full detennina
tion of their potential operating characteristics and the specific
evaluation of safety and human factors. However, sufficient detail is
available to establish principles of operation, system dimensional
envelope, probable equipment operating characteristics, approximate
installation costs, and other similar data necessary to evaluate the
respective system designs.
Site adaptability, an important factor affecting the general
use of AMWS(s} in both new and existing installations, varies consid
erably between the system with some designs forming a single linear
- 2 -
configuration similar to existing moving way systems, and other designs
forming loop or 11 S11 shaped configura,tions. Production capabilities of
AMWS developers likewise range fr001 well-established manufacturers in
the moving way transportation industry who have the resources and ex
perience to supply, install and logistically support a demonstration
AMWS with high levels of confidence for the sponsor, to individuals
without industrial backing who would be incapable of manufacturing and
testing satisfactory AMWS hardware within the Demonstration Project
time frame.
This report establishes the current state-of-the-art of AMWS
technology, the current development status of possible candidates for
a public demonstration, and su1T111arizes the available operating charac
teristics and performance, design details, dimensions, equipment data
and other information necessary to describe the respective candidate
systems. System safety and human factors, a primary demonstration con
sideration, is the subject of a separate project study, Report c
Accelerating Moving Walkway System Safety and Human Factors.
This report is comprised of a general discussion and classi
fication of moving way transportation systems, a brief history of mov
ing way system development, description of conventional single speed
systems and comparative summaries and assessments of the five AMWS
systems currently at, or near, the hardware stage of development.
- 3 -
1.1 Moving Way Transportation System Classifications
Moving way tramsportation systems are carriers providing con
tinuous service with passengers boarding the moving system rather than
batch boarding of stopped vehicles. The advantages of continuous ser
vice systems are high passenger capacities relative to system speed, and
the elimination of waiting and batching loading times. Other advantages
include mechanical simplicity as compared to the equipment and control
sophistication required for automated guideway transit, and reduced
manpower requirements as compared to non-automated vehicular systems
using drivers. Escalators and moving walks are examples of constant
spP.ed pallet and continuous belt moving way systems in common use for
passenger transportation. A wide variety of continuous movement systems
utilizing pallets, belts, rollers, draglines, and other conveying methods
are in use for goods movement in industrial applications.
Despite many advantages of continuous service systems, they
are inherently constrained to a speed that is acceptable for the gen
eral population to board and exit from the system safely and conven
iently. Escalator and moving walk speeds in the United States are
governed by the American National Standards Institute Code, which sets
maximum speeds for escalators at 120 fpm (37 mpm) and level moving walks
at 180 fprn (55 mpm)* [1]. Inclined moving walks must operate at lower
speeds depending on their slope. In actual practice in the United
States many escalators operate at 90 fpm (27 mpm) and moving walks at
120 fpm. Escalator and moving walk operating speeds in Europe are
*Average normal human walking speed is 270 fpm (82 mpm).
- 4 -
higher than the United States nonn, with moving walks in .the Paris
Metro subway system operating at 164 fpm (50 mpm) and escalators in
the Leningrad subway reported at 180 fpm {55 mpm). A study of the use
of a variable speed escalator by the London Transport system showed that
optimal passenger capacity was attained at a speed of 145 fpm (44 mpm)
and that further increases in speed did not result in increases in
capacity [2]. Photo~raphic observation of pedestrians boarding escalators
showed that system utilization was related to individual human perfor-
mance, including perception and reaction capabilities, psychological
attitudes towards crowding, presence of baggage or other carried arti
cles, and in addition, traffic conditions. The accelerating var1abie
speed moving walkway would have entry speeds set at accepted nonns,
and then gradually accelerate passengers to higher line speeds, approx
imately double the speed of walking. Prior to exiting, the system would
gradually decelerate, reaching normal alighting speed at the exit.
Variable speed moving transportation systems including ac
celerating moving walkways have been proposed in a number of different
configurations, but only a few have reached the operating prototype or 11 hardware 11 stage of development. Table 1.1 following summarizes the major
accelerating system classifications.
Multiple Belt Systems - first proposed, built and operated in
the ninteenth century, and still commonly used at world 1 s fairs and
amusement parks where large volumes of passengers must be continuously
processed, these multi-stage systems overcome the restraint imposed by
human boarding speed limits by use of a slower speed moving walk to
- 5 -
TABLE 1 - AMWS CLASSIFICATIONS
MULTIPLE BELT SYSTEMS
PARALLEL BEL TS • MULTIPLE BELTS• EXPANDABLE BELT PLATFORMS· RUNNING RUNNING CONTIGU• LINEAR ARRAY SYSTEM (LINEAR CONTINUOUSLY OUSLY ACCELERATOR BY (SPEERS, RETTIG,
PFEIFFER & CANDELLA) STORER, SILSBEE)
PALLET SYSTEMS.:. • • FORWARD AND' CROSS SLIDE ·.
RECTANGULAR PALLETS SCIMITAR PAVEMENT LENTICULAR PALLETS LINEAR ARRAY (OVER-(MODIFIED) (NRDC) (GRAVITY ACCELERA- LAPPING PALLETS) (DUNLOP SPEEDAWAY) TOR) (CRESTWALK)
SYSTEMS .
SYSTEMS ..
EXPANDABLE MESH ' t,\,.· ROLLER
' EXPANDABLE DIAMOND EXPANDABLE MESH DEAN RESEARCH MESH SYSTEM WITH OVERLAPPING PENN-FLEX (AYR E'S SYSTEM) PLATES
(TRANS 18)
OR PLATE SYSTEMS ·.
OVERLAPPING LEAF .
ACCELERATING BOEING SYSTEM 'TRAX' ACCELERATING BELT WALKWAY (GEORGIA INSTITUTE (APL SYSTEM) OF TECHNOLOGY)
OTHER SYSTEMS
ROTATING DISC OSCILLATING ELECTRIC EPICYCLOIDAL DISCS PARISTAL TIC TRAVEL· ACCELERATOR APRON (VIETORS) LING WAVE (KRAUSS MAFFEI, (JACKSON & MORELAND) (CRANFIELD) LEBOULIS, TELE-CANAPE)
- 6 -
board a sequence of one or more progressively higher speed stages. In
some installations the higher speed stage provides seating [3]. Passen
ger disembarking from the system is accomplished by walking through pro
gressively slower speed stages until the safe exit speed stage is
reached [4].
Variations of the multiple belt concept have been proposed to
provide a continuous linear system similar to existing conventional
moving walkway rather than using parallel units. Jackson and Moreland,
in connection with a consulting study of a system of elevated moving
walkways for the City of Boston, proposed a linear array of conventional
moving walks in series, with progressively higher speeds to attain line
speeds several times the entry speed [5]. The consultant reco11111ended
thorough testing of the proposed system to determine user adaptability
to multiple in line speed changes, as well as to assess the safety ef
fectiveness of equipment details such as combplates and higher speed
handrails. Candella [6] and Pfieffer proposed linear belt systems in
which expansion of the belt surface would occur to produce acceleration.
Candella proposed a belt take up drum, somewhat comparable to a window
shade cylinder, which would deploy added belt length in the accelera
ting section, and take it up in the deceleration section. Pfieffer
proposed a sequence of intermeshing belts running at increasing speeds
which also would reportedly expand in the accelerating sections. The
problem with these systems is that any treadway belt which is required
to turn around a drum or cylinder with the necessary radius, forms a
potentially dangerous surface discontinuity which could trip or entrap
- 7 -
passengers. Other multiple platform systems developed include the
following:
Pallet Systems - Variable speed walkway systems using pallets
have the advantage that the treadway surface is solid beneath the pas
sengers' feet, avoiding problems that may be associated with the expan
sion of the treadway surface in the acceleration section of the walkway,
and its contraction 1n the deceleration zone. The contraction of the
walkway surface offers potential crowding or so called bunching hazards
should passengers move in too close in proximity to each other as the
walkway surface decreases. The Dunlop Speedaway system, which is advanced
to the production model stage of development, is an example of the
pallet design. Factory prototype units of the Speedaway have been suc
cessfully used by relatively large numbers of persons of varying ages
and physical capabilities [7]. The Dunlop system is described in greater
detail in Section 2.1 of the report. Variations of the pallet concept
have been proposed which employ pallets shaped in curved configurations
rather than the trapezoidal pallet used in the Dunlop system. Other
pallet concepts include the 11 Scimitar11 pavement system which would use
pallets shaped in interlocking curved sections having the advantage
that the system could be aligned in a horizontal curve or loop, and a
lenticular pallet system in which the treadway is comprised of alter
nate convex and concave platforms, which can also be used in curved
alignments [8].
Roller Systems - Would employ variable speed rollers in series
similar to the industrial conveyors used to move goods. The Dean Research
- 8 -
Corporation has built a small section prototype of a roller system, em
ploying l inch (25.4 mm) diameter rollers, which is described in greater
detail in Section 2.6 of the report. The Penn Flex Corporation proposed
a similar concept using grooved rollers in series.
Overlapping Leaf or Plate Systems - Consist either of grooved
intermeshing pallets, which slide over each other to produce expansion
or contraction of the treadway surface, or angled intermeshing leaves,
whose deployment angles determine treadway changes [9]. The Johns Hopkins
University, Applied Physics Laboratory (APL) built and has successfully
operated a prototype system employing the intermeshing leaf principle,
which is discussed in greater detail in report Section 2.3. The Regie
Autonome des Transports Parisiens {RATP - Paris Transit Authority) has
built and successfully operated a prototype of a grooved pallet system
called TRAX, which is described in report Section 2.2. The Boeing
Corporation has a similar concept under development which is illustra-
ted in Section 2.5.
Other Systems - There are many other accelerating variable
speed walkway proposals which have not progressed beyond the conceptual
phase, in a few cases because suitable treadway materials or mechanical
components are not available. Some systems are considered to raise sig
nificant human factors problems or have doubtful applications which miti
gate against further development. Some other AMWS concepts of interest
are the Rotating Disc Accelerator by Krauss-Maffei, the Oscillating
Electric Apron proposed by Jackson and Moreland, the Epicycloidal Disc
System of Vietors, the Paristaltic Travelling Wave proposed by the
Cranfield Institute of Technology, and Mann's Crestwalk [Ibid. 3, 6, 8].
- 9 -
The Krauss-Maffei proposal consists of a constant high speed
(13 mph) moving belt which is boarded and exited from a rotating disc
platfonn. Passengers enter an inner disc at ground level which serves
as a rotary lift carrying them to the inside of a rotating disc to which
they transfer and on which they walk to the periphery for transfer at
synchronous speed to the high speed belt. A small scale working model
of the system has been built. The oscillating elastic apron of Jackson
and Moreland uses constant acceleration to accelerate passengers from
zero to the main belt speed. The accelerator consists of an elastic
apron using a double array of longitudinal intenneshing tread ribs or
slats. One set of ribs rises and moves forward and then drops down to
return, the motion is then picked up by the next set of ribs to move
the passenger forward. The passenger speed increases in proportion to
the distance from the boarding point. Vietors patented a proposal 1n
1898 for a system using a disc shaped platfonn based on the kinematic
law of the cycloid, which is that the path traced by a point on the
circumference of another disc is that of an epicycloid. The principle
would be utilized to load passengers by the rotating disc between a
central stationary circular platfonn and a high speed moving annualr
platform. In the Cranfield Institute of Technology Peristal1c system
proposal, the propulsion is provided by traveling wave motion. A flex
ible tube is nipped by a roller to form a seal. When air is pumped into
the tube at one end, the resulting pressure wave propels a series of rol
ler mounted platfonns or pallets. Mann's Crestwalk proposal is based on
traveling velocity waves which permit a conveyor to be boarded or left
- l O -
at any point. This effect is produced by moving each platfonn or pallet
forward at a regular cycle of high and low speeds, but with a slight
phase difference between each platfonn. A passenger by walking forward
may maintain conveyance by stepping on the crests or high speed phases,
or by standing, decelerate to a low speed phase for alighting.
- 11 -
1.2 History of Moving Way Transportation Systems
Moving way transportation has undergone over a century of
development. (See chronology, Appendix.) Chronologically, the escala
tor was invented first, but it was the moving walk that was first built
and opened for public use. The history of moving way transportation
began in 1859 when an American inventor names Nathan Ames was issued a
patent for what he called Revolving Stairs. This primitive concept for
an escalator, which was never built, consisted of a series of steps
linked together to produce a continuous moving stairway. In 1892, a
patent for an 11 lnclined Elevator" was granted to Jesse W. Reno for what
was to become the first operational antecedent of the escalator. Reno's
"Inclined Elevator 11, as it was called, was a continuous moving ramp with
a sloping treadway surface fanned by a series of boards or pallets guided
and supported by rails. Board surfaces were covered with small rubber
cleats running parallel ta the d1'rection of travel to prevent passengers
from slipping on the inclined treadway, which was sloped at an angle of
30 degrees. To aid in smoothing the transition from moving to stationary
surfaces, and to prevent foreign objects from jarmning under the endplate,
comb-like prongs were mounted at the encis of the ramp. These prongs ran
between the rubber cleats of each board in the chain. Great care was
also taken to shield all moving parts in order that they would not come
in contact with passengers' clothing. The inclined elevator was equipped
with two handrails, at least one of which moved with the conveyor. The
movable handrails were continuous chains covered with flexible rubber
and a soft pile covering.
- 12 -
Though the patent for the 11 Inclined Elevator" was registered
in the spring of 1892, it was not until the fall of 1896 that the first
inclined elevator was installed at the Old Iron Pier in Coney Island,
New York. Thereafter, the Reno Inclined Elevator was sold in the United
States and Europe, and by the year 1900, a number of them were installed
in some large department stores in New York City and Philadelphia. Five
units were also constructed for the Paris Exposition of 1900, and an
other .was installed in the Crystal Palace at Sydenham, England. The
general acceptance of the Inclined Elevator was virtually guaranteed in
1900 when one hundred of them were ordered by the Manhattan Elevated
Railroad Company in New York City. The first of these was installed
at the Third Avenue and 59th Street Station, and were eventually con
structed at every principal station of the elevated railroad (EL). They
remained in service until the 11 EL 11 was demolished in 1955.
It is curious to note that another patent for an inclined ele
vator was issued in 1892 to a George H. Wheeler for a "Moving Stairway".
This stairway was similar to the Reno invention, but with the exception
that the treadway surface was fanned of individual stairs. However,
Wheeler's invention was never built, and the patent was sold to Charles
D. Seeberger in 1898. Mr. Seeberger then joined the Otis Elevator Com
pany, and in 1899 the first two prototypes of the step-type escalator were
constructed, with the first sold for commercial use in 1901. In its
early years of development the step-type escalator was not very success
ful. For many years thereafter, the only two markets for escalators
were department stores and public transportation. Between the years of
- 13 -
1900 and 1920, acceptance of the escalator was slow with only an average
of seventeen units sold worldwide per year. From 1900 to 1911, Otis and
Reno were the only companies in the world building escalators and in
clined elevators. Then in 1911, the two companies were merged when the
Reno Company was acquired by Otis.
From that time until 1920, both the Otis step-type and the
Reno cleat-incline type excalators were sold in almost equal quantities.
However, in the year 1920, the escalator was completely redesigned and
the best features of the step-type escalator and cleat-incline type
elevator were combined. Among the design features which evolved from
the combi.nation of features from the two escalator types, plus experi
ence gained from their operation were the following:
• Combplates - Before 1920, the steps at the floor landings of the
step-type escalator ran beneath a diagonal transition section or
11 shunt 11• This virtually pushed passengers off the escalator, forc
ing them to take an awkward sidewise step to the landing with one
foot while the other foot was still moving forward on the step.
This required a high de~ree of concentration and agility. The Reno
inclined ramp used comb-like prongs, twelve to sixteen inches long,
meshing with cleats on the treadway. This arrangement eliminated
the sideways step at the exit, but passengers disliked the jolting
affect of the long prongs and tended instead to either jump off, or
take a large step over the prongs, frequently causing them to fall.
These problems were solved by creating a combplate with much shorter
prongs which were made with grooves on the escalator step, much like
present day designs.
- 14 -
1 Speeds - Originally, the cleat-incline elevator and the step-type
escalator were driven at speeds that varied between 80 and 100 fpm
(24-31 mpm). In 1920, the speed was standardized at 90 feet per
minute (27 mpm). Currently, speeds of 90 fpm and 120 fpm are in
common use in the U.S.A.
1 Handrails - The handrails of the first inclined escalator were chains
covered with solid rubber and guided by a lubricated steel channel.
This lubrication soiled passenger's hands, gloves, or clothing and
the design was abandoned in favor of the one used on the step-type
escalator, which consisted of a tension-driven rubber and canvas
handrail that was guided by a simple unlubricated channel. Sometime
later, pinch-proof h~ndrails were inaugurated in order to prevent
passengers' fingers from getting caught under them.
Further improvements made in the escalator in the years fol
lowing 1920 were as follows:
• Steps - Until the 1930 1 s, escalator steps were constructed of wood.
After that time, the wooden steps were abandoned in favor of the now
common, narrow-gauge cleat-type diecast metal step. The narrow gauge
was introduced in order to keep high-heels and other objects from
snagging or lodging in the cleats and wider spaced combplate.
• Extended Balustrade - An important improvement in escalator design
occurred when the balustrade and handrails were extended beyong the
comb-plate. This simple design change improved escalator safety by
encouraging passengers to grasp the handrail and adjust to the speed
of the unit before stepping onto the moving surface, and also to the
- 15 -
stationary pavement when exiting. The balustrade and handrail exten
sion also moved the return, or point at which the handrail entered
the balustrade, away from where it could entrap passenger clothing
or hands.
Moving Walkways - evolved concurrently with the development
of escalators. The first recorded proposal for a continuous moving
platform was made in the year 1874 by an American engineer named Speer.
The system, which was proposed for lower Manhattan, was an elevated
loop consisting of continuously moving platforms running at a speed of
about 15 mph (25 kmph), boarded from motorized 11cabins 11 that picked
passengers up from a standstill position at station platforms. From
1875 to 1900, a host of proposals and patents for moving platforms were
recorded in the United States and Europe, but of these only three were
built, the 1893 Chicago Columbian Exposition, the 1896 Berlin Indus
trial Exposition, and the 1900 Paris Exposition. The Columbian Expo
sition installation was a 2-speed system with platforms operating at
speeds of 264 and 528 feet per minute {80.5, 161 mpm), with the slower
platform being used for boarding and exiting. The system was laid out
on a mile long oval path in Jackson Park, near Chicago. The fast plat
form featured transverse seats, while the slow one was equipped only
with handposts installed at 12 foot (3.66 meter) intervals. Their
function was to aid passengers in getting on and off the platform. The
system erected in the Berlin Industrial Exposition in 1896 was almost
identical in principal of operation and construction to the one at the
Columbian Exposition.
- 16 -
Reno inclined elevator - Paris Exposition, 1900.
The moving platform installed at the 1900 Paris Exposition, photo illustrates low speed boarding and exiting stage at right, higher speed stage at left.
- 17 - FIGURE 1.1
The Parfs Exposition installation was one of the largest and
most successful of the earlier systems, and the first example of an·ac
celerated moving walkway system since there were no seats on the high
speed section. The moving platforms were similar to those at the
Columbian Exposition in 1893 in that they were a series of connected
flat trucks continuously moving in parallel and contiguous paths, but
they travelled at 196.8 and 393 feet per minute (60, 120 mpm). Its
total length was about 2 miles (3.36 kilometers). One of the major
reasons that this system was considered to be such a great success was
its excellent safety record. During the seven months of its operation,
it carried 6 1/2 million passengers with a total of only 40 minor
accidents reported.
In the fall of 1904, a group of leading railroad officials
put forth the idea of constructing a moving platform under 34th
Street, New York City, which was to run crosstown between First and
Ninth Avenues. The system was to have four platforms, three running
continuously at 264, 528, and 792 feet per minute {80,161,242 mpm),
and a fourth auxillary platform running at 264 fpm (81 mpm) only
during off hours when the other platforms would be shut down
for inspection and maintenanca. The fastest platform of the series
was to be fitted with transverse seats. The proposal was widely
promoted and recommended, but due to objections of the Rapid Transit
Commission at the time, it was never accepted.
In 1905, Adkins and Lewis, two British engineers, introduced
the concept of using a system of variable-pitch screws to continuously
drive a system of individual four-seat cars. These cars were to travel
- 18 -
at 176 feet per minute (54 mpm) through the station in order to allow
passengers to board and disembark and then accelerate to 1320 feet
per minute (412 mpm) between stations. The system, which was called
the Never-Stop Railway, was constructed and put into operation at the
British Empire Exposition in Wembley, England, in 1925. The railway
operated successfully for two seasons during which time it carried two
million passengers without a single accident. Moreover, it ran every
day for six months without a mechanical breakdown.
During the period 1905 to 1939 there were only two reported
proposals for moving way systems. One was for a moving platform
to run under 42nd Street in New York City from Grand Central to
Pennsylvania Stations, and the other was the Biway Underground Rail
System. The 42nd Street proposal was to replace the existing subway
shuttle service. The speeds and proposed configuration was similar in
many respects to the 34th Street proposal of 1904, with the exception
of the fourth standby walkway. One interesting difference between
the two proposals was the intention to power the 34th Street system
with linear induction rnotprs, rather than conventional motors. This
would have required less depth in subway construction because of the
horizontal plane of the linear induction motor. For reasons not known,
the system was never constructed, although a complete demonstration
unit was built on a Jersey City lot. (Figure 1 .2) In 1935 the Westinghouse Electric Corporation proposed a
two stage moving way system called the Biway Underground Rail System.
The high speed or'express platform was to move continuously at 1320
- 19 -
Full scale model in Jersey City of a 1924 Putnam Proposal for a three stage continuous loop system to replace the N.Y.C. Times Square Shuttle. Seats positioned on the high speed section.
The General Motors two stage conveyor system of the type used at 1939 and 1964 World's Fair Exhibits, New York City.
FIGURE 1.2 - 20 -
fpm (403 mpm) and be fitted with transverse seats. The local or
transfer platfonn was to vary in speed from zero, the boarding
speed to the express platfonn speed of 1320 fpm. Boarding and exiting
of the system was 11 pulsed 11 using automatically controlled gates which
would allow entry to the local stage when the system was stopped and
entry and exit from the high speed express section when the local
section was in operation. Although the costs to run this system were
estimated to be much less than those of running an ordinary subway
system, the idea never reached fruition.
In 1939, the General Motors Building Futurama Exhibit at
the New York World's Fair was equipped with a conveyor system that
transported visitors through a portion of the exhibit on a continuously
moving platform of seats. Passengers boarded this moving conveyor
from a continuously moving horizontal loading platform or moving
walk. In order to get a seat on the moving conveyor, passengers
boarded the moving walk from a stationary platform and disembarked from
it on to the moving conveyor which was running alongside the moving
walk at precisely the same speed.
An innovative aspect of the system was its circular unloading
platform. It was approximately 32.8 feet (10 m) in diameter and
it was surfaced with continuous, concentric aluminum cleats. The
edge of the unloading platform came into contact with the moving
conveyor and rotated at the same speed as the conveyor. The unloading
platform also came into contact with a stationary platform that had
cont>plates on it which meshed with the concentric cleats of the unloading
- 21 -
platform. To exit from the exhibit, passengers left their seats
on the moving conveyor, stepped onto the unloading platform, rode it
around to the stationary platform and stepped off onto it.
Current Conventional Moving Walkway Systems - fall into two
categories, those with a treadway consisting of grooved, continuous
rubber belt, and the .pallet type with a treadway comprised of a series
of grooved metal pallets similar to an escalator. Belt systems were
introduced in 1952 when the first continuously moving rubber belt
used for the transportation of people was installed in the B. F.
Goodrich Company exhibit at the Chicago Museum of Science and Industry.
It was a smooth belt, 36 inches (0.9 meters) wide that travelled at
a speed of approximately 50 feet per minute (5 mpm). It moved by
sliding along on a polished maple bed and had handrails that moved
at the same speed as the belt. The Goodyear Tire and Rubber Company
in conjunction with the Stephens-Adamson Manufacturing Company
introduced a belt system that was to be used as~ loading stage for
the proposed Carveyor System. This belt dtffered from the Goodrich
belt in that it ran on rollers to reduce friction losses, rather than
on a flat slider bed.
Another belt system, the Hewitt-Robins Glide Ride, was in
stalled in the Love Field Airport Terminal Building, Dallas. Texas in
1958. The surface of this moving walk consisted of a continuous, smooth
rubber belt which rode over individual, flat pallets that were linked
together. In this system, the pallets supported the load of the pas
senger, and the smooth rubber belt simply covered the pallets and the
- 22 -
gaps between them. Whether it was due to the lack of a suitable safety
code at the time, or just an engineering oversight, the system did not
include combplates at the ends of the moving belts. The end-plates were
flat, scraper type blades under which the smooth belt disappeared. For
eign matter and articles of clothing could lodge between the end-plates
and the belt. In 1960, this end-plate design contributed to the cause
of a tragic accident. A little girl sitting on the belt was strangled
by her clothing when it became trapped between the belt and the end-plate.
In subsequent designs, the entrapment hazards created by the smooth-belt
was significantly reduced by using grooved belts combed by a combplate at
belt ends. Despite the tragic experience with the airport installation,
the Glide Ride had innovative features in that it could follow the con
tours of a curve, making possible the return of the belt to serve as a
walk in the opposite direction.
- 23 -
1.3 The Modern Escalator
The features of the modern escalator are described in this
section for purposes of later comparison with accelerating walkways.
Current conventional moving walkways are similar in most respects to
the escalator. Externally, all that can be seen of a modern escalator
is its continually moving steps and handrails, but beneath these steps
and the sides of the balustrade enclosure is a relatively complex
driving mechanism. The operational components in an escalator can be
categorized into three functional drive systems; main, step, and hand
rail. (See Figure 1 .1). The main driving mechanism is comprised of the
escalator motor, worm gear, main drive sprocket and driving chain. The
handrail and step drives are connected to the main drive sprocket. The
handrail consists of a continuous hard neoprene rubber loop, tensioned
and carried over pulleys at both ends of the escalator. Escalator steps
are linked together in a continuous loop by the slip chain which is also
connected to the main drive mechanism. Each step is fitted with step
wheels, which are supported and guided by running tracks. All of these
components are mounted on a steel truss that supports the entire load
of the escalator and its passengers.· The main drive motor usually is a
three-phase induction motor in the 25 to 35 horsepower range, depending
on the width and rise of the escalator. Steps are nonnally fabricated
of cast, grooved aluminum alloy riding on two pairs of hard rubber
tired wheels. Each wheel rolls on steel tracks forming the path in
which the steps and connecting step chains move around the escalator.
A second pair of wheels is mounted at the bottom of the curved riser
- 24 -
"Tl -C) C: :a m ..... w
N (,J7
COMB PLATE
LOWER TENSION CARRIAGE ASSEMBLY
Source: OTIS ELEVATORS
A TYPICAL ESCALATOR
SKIRT SAFETY SWITCH
BALUSTRADE
STEP WHEEL TRACK
STRUCTURAL STEEL TRUSS
HANDRAIL PULLEY
HANDRAIL DRIVE CHAIN SPROCKET
DRIVE DETAIL
of the step, also running on a track which sets the height at which the
step rides at different points in its travel. The continuous, steel
step chains that draw the steps up or down the incline and around the
return also have roller wheels on them riding in tr~cks. to provide for
smooth, quiet running. Escalator handrails are fabricated of hard neo
prene rubber on a fabric cord body with steel tape or steel wire running
longitudinally through it. They are drawn by friction contact over pul
leys at the lower and upper landings of the escalator and slide on guides
mounted on top of the balustrades. Power to drive the handrails is pro
vided by the upper handrail pulley connecting with the handrail drive
sprockets, drive chain and main escalator drive, which results in the
handrail operating at a synchronous speed with the steps.
Every escalator or moving walk must be provided with an elec
trically released mechanically applied brake capable of stopping and
holding the treadway at rated load. These brakes must automatically
stop and hold the treadway when power to the drive motor fails or when
any other·safety device is activated. In cases where the drive mechan
ism is connected to the main drive shaft by a chain, and where there is
a brake on the main drive shaft, it is required that there be a device
that will activate that brake if the main drive chain of either step
chain fails. The same is true for a failure of the connecting link
between steps or pallets.
- 26 -
1.4 Manufacturers' Survey
A manufacturers' survey was conducted as the initial phase
of the assessment of Accelerating Moving Walkway System technology.
The purposes of the survey were to infonn the moving way system indus
try of the AMWS demonstration program, obtain more details on prospec
tive system concepts, and to detennine development status of systems.
that might be available for a public demonstration. A total of 36
potential AMWS suppliers were canvassed as part of the survey. These
prospective suppliers were identified on the basis of known work on
AMWS development, appearance in the literature, or as being known
manufacturers of escalators and moving w~lks. Some suppliers have
shown interest in the AMWS program but have not shown sufficient
development progress nor interest in the program to warrant inclusion
in the final demonstration project report.
The survey resulted in the identification of five potential
AMWS developers at, or near, the hardware prototype stage of develop
ment. These include, in the approximate order of their development: (1)
Dunlop Speedaway. (2) RATP TRAX, (3) Applied Physics Laboratory (APL),
(4) Boeing Corporation, and, (5) Dean Research Corporation.
- 27 -
2.0 DESCRIPTIONS OF CANDIDATE SYSTEMS
There have been a great many proposals for variable speed
moving way transportation systems, but only five developers have been
currently identified as being sufficiently advanced in system develop
ment to be considered as prospective candidate suppliers of an opera
tional unit for the subject public demonstration program. The basic
principles of operation and equipment details of these systems are
described and illustrated in this section of the report based on in
formation supplied by the five developers. A following report section
deals with a comparative evaluation of the various factors that would
affect the possible selection of a system for a public demonstration.
Safety and Human Factors considerations for the various systems, as
noted previously, are developed in more detail in Report c of the series.
- 28 -
2.1 The Dunlop Speedaway System
The Dunlop Speedaway is the most advanced variable speed
accelerating moving walkway system in terms of development, with a
background of more than ten years of design, prototype manufacture, and
evaluation, equipment component refinement, and user tests. Dunlop cur
rently has available a full scale pre-production model of its system and
could fabricate a production system for demonstration on order within a
period of about 18 months. Dunlop is a well established manufacturer
of escalators and moving walks in Britain, with licensees in other
European countries. Its French affiliate is responsible for the exten
sive installation of the conventional Dunlop Starglide passenger con
veyors at the new Charles de Gaulle Airport.
The Speedaway variable speed moving walkway is a one-directional
(and reversible) system employing a treadway comprised of wide trape
zoidally shaped aluminum extruded pallets linked to each other and sup
ported by rollers running on a tracked guideway. (See Figures 2.1-2.4).
Unlike other systems where the treadway surface expands and contracts
to provide acceleration and deceleration, the Dunlop treadway surface
area remains relatively constant, with the pallets gradually shifting
in both a forward and lateral direction to produce variations in speed.
The entrance of the Speedaway resembles an escalator or conventional
pallet type moving walkway with the exception that it is much wider.
The width of the Speedaway pallets and entrance is determined by the
system speed ratio. Overall pallet width across the extremities of the
1:5 speed ratio system is 22 1 -7 11 (6.9 m) and the clear entrance width
- 29 -
DUNLOP SPEEDAWAY
<Yi;; ",/-,)\';)'>\,' ~·· GENERAL VIEW DUNLOP SPEEDAWAY FULL SCALE FACTORY INSTALLATION. TREADWAY SURFACE COMPRISED OF GROOVED PALLETS SLIDING TRANSVERSE TO EACH TO PROVIDE ACCELERATION, DECELERATION. TOP CURVED ENTRANCE SECTION, BOTTOM, CONSTANT SPEED SECTION IN STRAIGHTAWAY. NOTE MULTIPLE HANDRAILS. EACH OF THESE HANDRAILS OPERATES AT A CONSTANT SPEED, 4 HANDRAIL TRANSITIONS FROM ENTRY TO CONSTANT SPEED.
- 30 - FIGURE 2.1
or portal is 9'-9" (3.0 m). The forward and lateral trajectory of the
pallets producing the Speedaways 1 variations 1n speed results in curved
acceleration and deceleration zones and an 11 S11 shaped alignment config
uration.
The Speedaway handrail system is comprised of a sequence of
conventional constant speed handrails of the familiar escalator type
running in series. The handrail design for the 1:5 ratio system consists
of seven separate constant speed handrails, with the handrail speed for
each segment set at the average speed of the walkway section within
that segment. Dunlop has designed the handrail sequence so that there
is a minimum displacement of hand position relative to body position
during passenger movement along the acceleration and deceleration sec
tions. The high speed section handrail runs at the same speed as the
treadway. Balustrade detailing in handrail transition sections have
also been designed to facilitate hand transfer between handrails, as
well as to avoid possible passenger entrapment or catching of hand
carried articles. {See Figure 2.3.)
A simple, rubber tired friction driving mechanism powered by
an electric motor is utilized to propel the continuous loop of linked
pallets forming the treadway over the constant speed section. Handrails
are driven by chain linkages and pulleys somewhat similar to the arrange
ment of the conventional escalator described in report Section 1.3.
Comb-plating for the Speedaway resembles that of conventional escalators
and pallet type moving walks. Speedaway requires a level, or nearly
level installation site.
- 31 -
DUNLOP SPEEDAWAY
VIEW OF SPEEDAWAY EXIT ILLUSTRATING GROOVED PALLETS AND STATIONARY COMBPLATE.
- 32 - FIGURE 2.2
•
DUNLOP SPEEDAWAY
CLOSE UP OF HANDRAIL AND BALUSTRADE TRANSITION SECTION AND TREADWAY. TRIANGULAR, NON-GROOVED TREADWAY SURFACES EMERGE FROM BENEATH BALUSTRADES IN ACCELERATION ZONE, RETREAT BENEATH BALUSTRADE IN DECELERATION ZONE.
FIGURE 2.3 - 33 -
DUNLOP SPEEDAWAY
SPEEDAWAY SUPPORT FRAME AND DRIVE MECHANISM.
RUBBER TIRE DRIVE MECHANISM AND TREADWAY PALLET AND BOGIES. TREADWAY PALLET RETURN.
- 34 - FIGURE 2.4
2.2 RATP TRAX System
The TRAX system, under development by the Regio Autonome de
Transports Parisiens (RATP - Paris Transit Authority), is a full scale
variable speed walkway prototype developed to the point where a public
demonstration is prograRJ11ed in Paris for early 1979. The Authority is
not a manufacturer like Dunlop, and therefore would require a licensee
to fabricate, install and support a production model of the system for
a United States demonstration. The treadway and a partially operational
handrail for the TRAX system has undergone user tests. (See Fiqures
2.5 thru 2.8.)
The TRAX variable speed passenger conveyor is a two directional
loop system with a continuous treadway comprised of grooved, intermeshing
and overlapping pallets, sliding over and combing each other, and combed
by means of conventional combplates at the entry and exit to the system.
The longitudinal sliding movement of the pallets required to produce
the expansion and contraction of the treadway surface necessary for ac
celeration and deceleration is controlled by a continuous closed loop
quadrangular chain linkage on the underside of each pallet. The move
ment of the connecting chain and plates is in turn controlled by
sprockets and a telescoping tube assembly running in variable gauge
tracks flanking the underside of the treadway. The spacing or gauge
of the running track determines the configuration of the undercarriage
assembly of sprockets, telescoping tubes and connecting chain linkages,
the movement of the treadway pallets. The tracks are spread wider and
overlapping pallets meshed closer together in the slow speed sectfon
of the conveyor and conversely, the tracks are closer together and
- 35 -
RATP TRAX
GENERAL VIEW OF TRAX PROTOTYPE LOOP. TREADWAY SURFACE FORMED OF GROOVED SLIDING PLATES, COMBING EACH OTHER AND COMBED BY STATIONARY COMB PLATES AT ENTRY AND EXITS.
SIDE VIEW TREADWAY SURFACE, EXPANDED HIGH SPEED CONFIGURATION, GUIDEWAY TRACK, ROLLERS, AND PLATE CONTROL CHAIN.
- 36 - FIGURE 2.5
RATP TRAX
illJlllll\l\\\\{l
A CONSTANT LENGTH CHAIN, CONTROLLED BY ROLLERS, ANO A VARIABLE GAUGE TRACKED GUIDEWAY PROVIDES THE SPEED VARIATION IN THE TRAX SYSTEM. THE GUIDEWAY DETERMINES THE CHAIN CONFIGURATION SHIFTING TREADWAY SECTIONS TO ELONGATE AND CONTRACT THE WALKWAY. TOP: SLOW SPEED CONFIGURATION. BOTTOM: HIGH SPEED CONFIGURATION.
FIGURE 2.6 - 37 -
RATP-TRAX
The Trax Handrail is comprised of individual handgrips superimposed upon a continuous articulated hand hold. ,
- 38 - FIGURE 2.7
TRAXSYSTEM
ENTRANCE/EXIT RAMP
CONTINUOUS HANDRAIL
TREADWAY ---==-=------
TREADWAY LOOP MACHINE CHAMBER
CROSS SECTION TRAX HANDRAIL RETURN CONFIGURATION.
FIGURE 2.8 - 39 -
overlapping p~llets spread longitudinally further apart in the high
speed section.
The TRAX handrail desi_gn consists of a solid individual hand
grip and a continuous articulated section handhold linked to the driv
ing mechanism, so that the handgrip operates at the same speed as
the walkway. (See Figure 2.7). The articulated section handhold,
actually the cover over the handrail driving chain, could be grasped
for support if necessary, though providing a less comfortable grip.
Use of individual handgrips would help in spacing the passengers to
limit bunching which has been identified as a potential problem on
linear variable speed walkway systems such as TRAX (see Report c for
details). Because of the loop configuration of the TRAX system, as
well as its unique handrail design, the handrail return would be dif
ferent than that of conventional moving walk systems and the Speedaway.
As shown in Figure 2.8, the handrail would follow an angular path into
the treadway loop machine chamber at the ends of the system. Balustrade
detailing in other sections of the walk would be similar to conventional
system designs. Combplating would also be similar to conventional de
signs. The main drive mechanism and various chain drive linkages for
the pallets and handrails is somewhat similar to that previously des
cribed for the conventional escalator.
Reportedly, the TRAX system can be adapted to vertical curve
radii of 25 m, and horizontal curve radii of 50 m, as well as grades
of up to 15%. (Note: Grades would be subject to code restrictions re
lated to speed.) The added vertical and horizontal alignment flexibil-
ity of the system would help increase its potential number of applications.
- 40 -
2. 3 Applied Physjcs Laboratory (APL}. System
The Johns Hopkins University (APL) variable speed walkway
exists as a 31 ft. long (9.5 m), 18 inch wide (457 m), laboratory
prototype which has undergone several years of operational and user
testing. The University is, of course, not a potential manufacturer
of the system, and would require a licensee or other type of contract
arrangement to produce a fu·11 scale production model and support
a demonstration. There has been limited development progress on the
system since it was first built and tested because of the lack of
funds. The prototype, which is a l:3 speed ratio unit, has been in
use with a stationary handrail. A variable speed handrail concept has
been designed, but not fabricated or demonstrated.
The APL variable speed passenger conveyor is a linear one
directional (and reversible) design using a treadway comprised of over
lapping and intenneshing leaves, combing each other, and combed at the
system entrance and exit. (See Figures 2.9-2.12.) The leaves are
linked together to form an endless chain and are supported by a vari
able gauge track. The elongation and contraction of the walkway sur
face necessary to provide acceleration and deceleration of the system
is accomplished by variable pitch screws beneath the treadway which
change the treadway leaf angle. In the contracted or slow speed con
figurationt the interconnecting leaves are deployed 1n an elevated
position, whereas in the expanded high speed configurationt they move
into a position nearer to the horizontal. Each of the individual con
necting leaves fanning the treadway is curved in such a way that the com
posite surface remains practically level during changes in the leaf angle.
- 41 -
.i:,. N
-n -C) C ::l:J m N TREADWAY SURFACE IS FORMED OF INTERMESHING LEAVES VARIABLE PITCH SCREW DRIVING UNIT CONTROLS TREADWAY co COMBING EACH OTHER AND COMBED AT ENTRY AND EXIT. LEAF ANGLE AND THE ELONGATION AND CONTRACTION OF
THE TREADWAY SURFACE.
)> "ti r-
~· ..
.,, -G) C: ::r, m 9') • .. C)
.i:,. w
VIEW SHOWING STATIONARY COMBPLATE AT END OF PROTOTYPE UNIT.
l> -a r-
TREADWAY SURFACE. (a) STEP ON SPEED (b) ACCELERATION SECTION (c) CONSTANT HIGH SPEED SECTION.
BASIC LEAF AND LEAF DETAIL.
APL
- 44 - FIGURE 2.11
.,, -C) C: ::D m !') ..... I\)
.s::,. u,
/ I
'
ACCELERATING HANDRAIL CONCEPT
COMPRESSIBLE RAIL
....
SIDE VIEW
CARRIAGE
--- --
.......___ ____ _
RAIL
-C:,-
END VIEW
COMPRESSIBLE RAIL
CARRIAGE
RAIL~
CHAIN
SCREW ~
WALKWAY SURFACE
~-- .... , .........1~--__.___.
)> .,, r-
Balustrade and combplate detailing for a full scale system
would be similar to that of conventional moving walks. The APL hand
rail concept 1s based on the use of a compressible accordion type
handrail which would synchronously expand and contract with the tread
way surface. The variable pitch screw driving mechanism in accelera
tion and deceleration sections would be supplemented by a chain drive
in the central constant speed section in longer installations. As
with all linear systems, the APL system is subject to pedestrian
bunching and appropriate measures would be required to limit this
problem.
The APL system has the advantage of dimensional compatability
with existing one-directional conventional moving walkways and, there
fore, could be used for retrofitting. The system could also be built
in varying widths and be adapted to limited vertical curves and to the
maximum grades allowed by the revised code.
- 46 -
2.4 .The Boejng System
Boeing Company is developing a varia.ble speed pedestrian con
veyor with prototype completion scheduled for late 1978. While the
system development had not advanced to the same degree as the others
discussed in preceding sections, considerable confidence exists in the
ability of the Boeing Company as a manufacturer of transportation
equipment to produce a demonstration unit and to provide the necessary
logistic support for a demonstration.
The Boeing system resembles TRAX in many respects. Like TRAX,
it is a linear system configured in a two directional loop, and utilizes
a treadway of grooved overlapping and intenneshing sliding pallets.
(See rendering, Figure 2.13.) The sliding pallets would be mounted on
rollers running in flanking tracks. Propulsion would be supplied by a
linear induction motor. Variable speed perfonnance would be achieved
by cam tracks and linkage mechanisms to provide the changing overlay
of the intenneshing pallets. The spread of the pallets and length of
the treadway would be increased in the acceleration section and decreased
in the deceleration section. A matching speed handrail is proposed em
ploying overlapping sections to fonn a telescoping variable speed hand
rail for the acceleration/deceleration areas. Site adaptability of the
Boeing system would be favorable because its relatively shallow depth
would pennit practical on grade installation.
- 47 -
BOEING
RENDERING OF TELESCOPING HANDRAIL AND TREADWAY. TREADWAY GOMPRISED OF GROOVED SLIDING PLATES ARTICULATED BY UNDERCARRIAGE RUNNING ON TRACKS. LINEAR INDUCTION MOTOR DRIVE.
MOCKUP OF TELESCOPING HANDRAIL, BOEING SYSTEM.
- 48 - FIGURE 2.13
2.5 Dean Research Corporation System
The Dean Research Corporation, a manufacturer of specialized
industrial conveyor systems has built a short prototype for a linear
one directional (and reversible} variable speed walkway based on the
use of a series of abutting steel rollers. The prototype has undergone
limited tests with passengers of varying ages, types of footwear, and
physical handicaps, reportedly with encouraging results. Because of
the modular simplicity of a roller treadway concept, 1t potentially
could be fabricated in a relatively ~hort time. Such a system would
be highly site adaptive because of its shallow depth and could be de
signed for horizontal and vertical curve alignments as well as for
limited grades. (figure 2.14}
The basic principle of the system is the p~graR1Tiing of in
dividual rollers for different speeds to produce gradual acceleration
or deceleration. The propulsion system would consist of a series of
motors with drive connections to the rollers. An operational hand
r&il has not yet been developed, but a solid roller driven handgrip,
running at a speed synchronous witn the treadway speed has been pro-\
posed by the developer. Insufficient design details or user accept-
ance data is available to adequately evaluate this system at this
time. Individual powered rollers could limit possible consequences of
entrapments. Additionally, since there would be no contraction of the
treadway surface as with other linear systems, bunching effects should
be minimized.
- 49 -
DEAN
THE DEAN RESEARCH CORPORATION PROTOTYPE IS A LINEAR SYSTEM CONSISTING OF A SEQUENCE OF ABUTTING 1" (25.4mm) DIAMETER VARIABLE SPEED STEEL ROLLERS.
FIGURE 2.14 - 50 -
3.0 SUMMARIES OF SYSTEM CHARACTERISTICS
The use and acceptance of accelerating variable speed
moving walkway systems will not only be based on the identification
of potential useful applications and existence of sufficient user
demand, but consideration of other factors as well. Among the factors
that will require consideration are:
• Site Adaptability - relating to the configuration, dimensions,
alignment flexibility, structural requirements and the basic
physical envelope of the system;
• Performance Characteristics - system speeds, acceleration,
deceleration, capacity, safety features;
• Costs - manufacturing, furnishing and installation, site- preparation,
operations and maintenance, insurance;
• Developers Qualifications - experience, production capabilities,
installation capabilities, financial resources, support capabilities
for maintenance, repair, replacement parts, (etc);
• User Acceptance - system appearance, safety and human factors design,
installation environment, noise, vibration, heating, ventilation,
air conditioning, lighting, weather protection.
The various system aspects listed above are developed in
the following sections: 3.1 Siting Characteristics, 3.2 Passenger
Service Characteristics, 3.3 Costs, 3.4 Developer Qualifications,
and 3.5 Safety and Human Factors, (more detail on this subject pro
vided in Project Report c).
- 51 -
3.1 Siting Characteristics
The system configuration, its overall dimensions, structural
requirements, its relative adaptability to on-site grade changes or
shifts in alignment are significant determinants of the number of loca
tions where an AMWS could be applied. The generalized plans and sec
tions of the five systems discussed in preceding sections of the report
are shown on Figures 3.1 and 3.2 following. Additional data is sum
marized on Table 3.1.
Naturally, systems with smaller dimensional envelopes are
simpler to site. The APL and Dean Research linear one-directional sys
tems have the smallest cross sections, and are adaptable to limited
changes in horizontal and vertical alignments, which make these systems
potentially useable in more locations, particularly where a one direc
tional movement situtation might be encountered. Both of these systems
are suitable for retrofitting or replacement of existing in-line conven
tional walkway systems. The Dean system as presently conceived is amen
able to surface mounting.
The Dunlop Speedaway has several dimensional restraints limit
ing its wider application. However, in new construction these dimensional
restraints would be less of a factor. The system's 11 511 configuration
(either normal or reverse 11511), inherent in the lateral acceleration con
cept, is a constraint where the direction of pedestrian flow 1s in a
straight line, or in existing structures with a rectangular grid column
spacing. The greater depth of the Speedaway due to its pallet return
chamber is a structural design and clearance factor in elevated sections
or where there are floor spaces in use beneath the system. The flaring
- 52 -
I zg_c;f
I
N~
PLAN VIEWS CANDIDATE AMWSS ALL DIMENSIONS APPROXIMATE· SUBJECT TO CHANGE
L (Varies)
HANDRAIL A2+i 6'-0" AUXILIARY WALi< (IN BRIDGE 8, TUNNEL SECTION ONLY)
29'-0"
1-1-1------1..-----~---' \-______ ...,. _______ ---1, ___ ----1,...; . ' \
I 11,:t,:J,J!,=,i~f,~:,/f ( w I
A2_.J
APPLIED PHYSICS LABORATORY· DEAN RESEARCH SYSTEMS
1a'-d' '-0"
SEGMENTED HANDRAIL
l <Varies)
DJ+1
6'-0" AUXILIARY WALK (IN BRIDGE Bi TUNNEL SECTION ONLY)
DUNLOP SPEEDAWAY SYSTEM
L (Varies)
T .J TRAX· BOEING SYSTEMS
ACCELERATION DECELERATION SECTIONS
28'-s'
29'-c:J'
0
lf/-ef
IO 40
- 53 - FIGURE 3.1
SECTION VIEWS CANDIDATE AMWSs ALL DIMENSIONS APPROXIMATE• SUBJECT TO CHANGE
2'-0" 5'-6" r~--1 :
I i
~. w l h· ·- .~. ~,,-
6'-0"
SECTION AZ-AZ SECTION A 1-A 1
APPLIED PHYSICS LABORATORY • DEAN RESEARCH SYSTEMS (FLOOR LEVEL MOUNTING THESE SYSTEMS POSSIBLE)
SECTION 0 2-D2
rt-·-·· ------, Lt ~-
24'.9•
SECTION D'•D'
DUNLOP SPEEDAWAY SYSTEM
SECTION B•B
BOEING SYSTEM FLOOR LEVEL MOUNTING POSSIBLE
(TWO-WAY)
FIGURE 3.2
W:4011 ±
- 54 -
SECTION T•T
TRAX SYSTEM (TWO-WAY)
n
"' "'
2.
3.
4.
5.
6.
1-~ ITEM DUNLOP SPEEOAWAY
Configuration One direction, reversible.
Width: Entry/Exit 30 ft. including pit areas.
High Speed 8 ft., 2 in.
Depth Below Grade:
Entry/Exit 57 in. (l)
High Speed 57 in. (1)
I
Maximum Grade !level site required
Alignment Adaptability:
Horizontal Curve Straight 11ne.
Vertica 1 Curve Radius 1640 ft.
Loading: Dead weight Varies, 8.3 K per support pad (in lb. in curved section, 1.4 Kin units} high speed
Loaded Weight Live load 45 #/SF
NOTES: (1) Equipment depth only.
ACCELERATING MOVING WALKWAY SYSTEMS
SITING CHARACTERISTICS
RATP TRAX JOHNS HOPKINS A.P.L.
Two directional Loop , One direction, reversible
I
BOEING
Two directional loop.
14-16 ft. throughout de1end-: Similar 40 in. tread escala- i 14-16 ft. throughout depend-ing on tread and siaewa k : tor, approx. 6 ft. throughouti ing on tread and sidewalk widths. I \ widths.
(•
: ! 7.4 ft. machine chamber depthl24 in. (1) i N.A.
I 18 in. (2) 20 in. (1) , 15 in. (1 l (2) i
l + 12-13% (3) !. 15% (3) :+ 27% (3) ;-
' i .. i i I
; ' 164 ft. \"ad min. Straight line : Straight line.
I
82 ft. rad. 50 ft. radius, high speed ;N.A., but possible. section. i
I
800 #/L ft. - accel/decel; Single lane: 90 #/LF. ! 60 !I/SF accel ./decel. 400 #/L ft. - high speed. : 50 # /SF high speed
I
1165 il/LF I
Live load 188 #/L ft. IN.A. I I
(2) Surface mounting of system possible with ramped approach.
TABLE 3.1
l ·- - ··- ----,
DEAN RFSEARCH I
' '
One direction, reversible. I I I
Similar 40 in. tread escala- : tor, approx. 6 ft. throughout
I
I
' ! I
IN.A., but similar to APL. I
I (zJ i
I+ 7% (3) !
N.A., but possible with tapered ro 11 ers.
N.A., but possible.
240 #/LF I
1440 #/LF '
(3) Grades will be subject to A17 Code limitations, 12-30% is commonly acc~pted industry maximum for conventional constant speed walkways.
out of the Speedaway at its ends. is ~nother dimensi.onal constraint which
requires significant clear space. A bi-directional s.vstem with two par
allel units would increase this requirement.
The TRAX and Boeing bi-directional loop systems have similar
dimensional requirements. Because of the loop configuration, each re
quires a sfte with relatively wide clear space, but the space in between
the walkways could be used for a sidewalk. Because the pallets for each
of these systems are returned on the surface, a relatively shallow depth
is possible for these systems, offering the potential of surface mount
ing. Greater depth is required at the ends of the TRAX system for a
machine room and pallet turning purposes. The Boeing end chamber require
ments would be less as presently configured. Reportedly, each of these
systems could adapt to limited horizontal and vertical curves and grade
changes.
A siting characteristic of all variable speed accelerating
moving walkway systems, which limits their installation in on-grade
installations is the frontage or barrier affect. An at grade AMWS
blocks intersecting pedestrian pathways not running parallel to its
alignment, similar to gufdeway or other exclusive right-of-way trans
port systems. As with other transportation systems, grade separation,
either above ground on a pedestrian bridge, or underground in a pedes
trian passageway, removes this restraint.
- 56 -
3.2 Passenger Service Characteristics
The utilization of an AMWS will be dependent on its adapta
bility to the transportation demand and traffic patterns in the intended
application, as well as passenger acceptance of riding characteristics.
Accelerating variable speed moving walkways are continuous service sys
tems offering advantages over vehicular batch load systems in many appli
cations. These advantages are discussed in greated detail 1n Report C
of the AMWS study series. Photographic studies of the passenger utili
zation of escalators and moving walks have indicated that practical
operating capacity is related to available entry or portal width and
the characteristics of the user population, including such factors as
individual psychological preferences to avoid crowding and contact with
others. [Ibid. 2] Treadway speed is less of a detenninant of moving way
system capacity, since the capacity limitation appears to be a human,
rather than mechanical, restraint. Even under the heaviest traffic
demand pressures, it is consistently observed that only 60-70 percent
of the available step positions are occupied on escalators. Produc
tivity comparisons between 90 and l~O fpm (27-37 mpm) escalators show
only about a 10 percent increase in utilization with the one-third in
crease to the higher speed. Other studies show optimum escalator capa
city occurring at about 145 fpm (44 mpm}, after which use levels off.
Reportedly, speeds of up to 180 fpm {55 mpm) are used in the Leningrad,
Russia subway system but no productivity or safety data is available.
It is conman practice in the United States to run many moving way
systems at the lower 90 fpm speed, such as in department stores, where
- 57 -
demands are not heavy and where the user population 1s comprised of
greater proportions of the elderly, or those encumbered by packages.
Additionally, trip times are less of a premium in these situations.
Since the entrance portal configuration for all but the
Speedaway variable speed walkways is comparable to existing conventional
escalators and moving walks, it is assumed that their effective capa
city will be equivalent to approximately 3600 persons per hour per 24
inches (610 mm) of width measured over the handrails. The Dunlop
Speedaway system represents a special case since the treadway width at
the entry portal for the 1:5 speed ratio system will be 9.75 feet (2.98 rn).
Higher potential occupancy would be possible with this system since it
would be theoretically possible for 5 persons abreast to board the
system. However, as a practical human factors consideration, it will
be desirable to channelize pedestrian traffic to assure passenger
proximity to a handrail, thereby resulting in only two effective ap
proach lanes.
Other perfonnance characteristics affecting the public ac
ceptability of variable speed walkways will be user adaptability to
treadway alterations. With the exception of the Dunlop Speedaway
system, which uses individual pallets similar to an escalator, AMWS
users will encounter a changing treadway surface beneath their feet,
either in the fonn of diverging and converging leaves, grooved inter
meshing pallets, or steel rollers of varying speeds. The standing
surface alteration will be a new sensation which some users may find
to be objectionable. Additionally, motion affects of acceleration,
deceleration, and the rates of change of these motions will be
- 58 -
encountered, but this is comnonly experienced on all modes of trans
portation. An objective of the AMWS public demonstration is to closely
observe through photographic techniques and analysis, the affects of
these motion characteristics on various categories of users, including
the elderly and handicapped.
The desirable standards for acceleration, deceleration and
rates of change of acceleration and deceleration, based on Project Con
sultant recommendations as well as other data, are developed in detail
in Report c of the Project study series - 11 AMWS - Safety and Human
Factors 11• It should be emphasized that the acceleration and decelera
tion of any of the systems is not locked into their design, and can be
changed to meet the specifications of the equipment purchaser. A con
sideration will be the recommended speed and other motion specifications
of the special ANSI Al7 sub-committee on accelerating variable speed mov
ing wa 1 kways.
Table 3.2 following summarizes reported accelerations, decel
erations, and rates of change of these functions for the five proto
typical systems. Each of the systems is capable of attaining the 1:5
speed ratio considered desirable for a demonstration mode AMWS. Effec
tive passenger capacity for all linear systems is estimated at about
7200 passengers per hour on the assumption of a 40 inch (1016 mm) tread
way. The Dunlop Speedaway system, with its wider entrance treadway con
figuration, would have potentially higher capacity depending on the
purchasers priorities for user handrail proximity. Table 3.2 also
su11111arizes the relative familiarity and ease of use of the respective
systems.
- 59 -
"' 0
1.
2.
3.
4.
5.
6.
ACCELERATING MOVING WALKWAY SYSTEMS
PASSENGER SERVICE CHARACTERISTICS (I) TABLE 3.2
I ~ MODEL DUNLOP SPEEDAWAY RATP TRAX 1
JOHNS HOPKINS A.P.L. : BOEING j\ IJEAN -R~SE~:c: ----. !ITEM------- , I I i I I Acceleration/ .04 G .10 G .08 G · .12 G
1 ,07 G ,
I Deceleration (2) : I ·
I I ;
I
Rate of Change {RCA) .04 G/sec. .06 G : .06 G .10 G/sec ! N.A. Accel ./Decel. (2) , 1
!
! Emergency Deceleration .10 G .20 G .15 G .20 G l N.A. (2) i
; l ' I
Overall Familiarity Wide curved entrance unlike Entrance and treadway conffg-: Entrance and treadway config- Entrance and treadway configj Entrance configuration sim-escalator, multiple 7 sect1or uration similar to escalator,: urat1on similar to escalator, uration similar to escalator ilar to escalators, but handrai 1, transverse shift o1 handrail grip, and handra 11 · accordion type handrai 1 un- tel escop1 ng handrai 1 unlike I ro 11 ers unioue. Handra i 1 pallets may confuse some. end condition unlike escala- · 11ke escalator escalator : details N.A.
tor.
! Treadway Surface Standing surface stable, Sliding of intermeshlng , Unfolding, folding rounded Sliding of intennesh1ng ; Multiple variable speed Changes transverse shifting of grooved pallets beneath feet.t leaf surfaces beneath feet. grooved pallets beneath feet.! roller movement beneath feet a
pallet. l I
User Learning Task Avoid straddling two pallets Adapt to surface changes. 1Ad4pt to surface changes, Same as A.P.L. I Adapt to rollers. Handrail • or standing on pallet tabs, hold handgrip, maintain pro-: handrail shape, maintain i details N.A. Bunching mini-sh1ft of body position to per spacing to avoid passen- I proper spacing to avoid I miied since tread does not direction of motion, use 7 ger bunching. '!passenger bunching : contract. section handrail. I
! NOTES: (1) Attainable speed ratios for all systems assumed 1:5, working capacft~ 3600 passengers per hour per effective pedestrian lane (24" over handrails).
! (2) Not an inherent system restraint, can be changed to suit purchasers' requirements; G • 32 ft/sec2, 9.8 m/sec2/ !
(3} N.A. - not available.
3.3 AMWS Costs
Accelerating var1ahle speed moving walkway systems will pro
vide cost effective solutions to transportation problems where traffic
volumes are sufficiently high to warrant installation, and where alter
native systems would be more costly 1n terms of installation, operation,
and total life cycle costs. The primary cost advantage of variable
speed moving walkways is their operational simplicity and concomitant
lesser manpower and skills requirements. The manned vehicular alterna
tive requires operating and repair personnel, as well as facilities for
the garaging and maintenance of vehicles. Automated vehicular systems
generally reduce total manpower requirements, but job skills shift into
categories requiring higher levels of training such as electronics.
Properly maintained moving way systems will have service lives exceeding
25 years. Repairs are mechanically simple, involving replacement of
basic parts such as chain linkages, rollers, pallets, handrails, comb
plates, etc.
Capital costs for an AMWS include the furnishing and installa
tion of the unit and the structural, architectural, and electrical system
preparation of the installation site. Operating costs would include
costs of power, insurance, maintenance personnel, and supplies. Addition
ally, heating, ventilation and air conditioning may be required in some
installations. Definitive costs for the furnishing and installation of J
an AMWS have not yet been determined because of the lack of production
experience. Conventional escalators and moving walks currently cost
between $1000 and $1200 per lineal foot ($3280-3940/m) for furnishing and
- 61 -
installation of a unit at the site. Accelerating moving walkway hard
ware does not differ substantially from that of existing conventional
escalators and walkways, suggesting that an early production unit AMWS
should be on an order of magnitude of about 50 to 100% greater cost for
furnishing and installation, or about $1500 to $2400 per lineal foot
($4920-7870/m). Naturally, the effective system route length for esti
mating the cost of a bi-directional loop unit would be approximately
double that of the one-directional unit.
Structural and architectural preparation costs for the var
ious systems vary according to the installation envelope comprised of
the sub-grade depth requirement and height and width of the system.
Shallow depth, one-directional linear systems would be the most cost
effective where only a single reversible 11 tidal flow 11 traffic direc-
tion was being served, for example at a sports complex. Preparation costs
would also vary according to whether the AMWS was installed on grade,
elevated on a pedestrian bridge, or undergound in a pedestrian subway.
Energy use and power cost on a passenger carried basis for ac
celerating moving walkway systems is less than vehicular transit because
the weight carried is greater in these systems (vehicle and passenger),
and because of the elimination of energy losses such as braking asso
ciated with vehicular operation. Insurance costs for an AMWS is currently
estimated to be comparable to that of an escalator since it is not anti
cipated that user risk will be any greater. A cost benefit evaluation
of an accelerating moving walkway installation is contained in Project
Report D. Approximate preliminary estimates of relative system costs
are contained on Summary Table 3.3, following.
- 62 -
a, w
r-1 ~L
-~
1 _ Estimated Cost Equipment (Ex-Factory)
a. 300 ft. ( 91 m)
b. 500 ft. (152 m)
C. 1000 ft. (305 m)
2. I Estimated Site Preparation Cost (2) (per lineal foot)
DUNLOP SPEEDAWAY *
(one direction)
$ 707,200
$ 966,450
$1,614,150
a. covered, at grade j $1860/L ft.
b. covered pedestrian t>ri dge j $2580/L ft.
c. below grade pedestrian subway I $4250/L ft.
3. Estimated Demand KW, Loaded, Cost per Running Hour (4)
i i
a. 300 ft. ( 91 m) 90 KW{$ 4.50/hr)
b. 500 ft. (152 m) 1120 KW ($ 6.00/hr)
c. 1000 ft. (305 m) 200 KW ($10.00/hr)
ACCELERATING MOVING WALKWAY SYSTEMS
PRELIMINARY COST DATA
RATP TRAX *
(two direct1on)
$1,500,000
$2,000,000
$3,000,000
Note (3)
I $1430/l ft.
$2650/L ft.
$4020/L ft.
50 HP/ 67 KW ($3.35/hr)
70 HP/ 94 KW ($4.70/hr)
100 HP/134 KW ($6.70/hr)
JOHNS HOPKINS A.P.L.
i ( one di rec ti on)
'$ 4a7 ,000
$ 692,000
'$1,200,000
$1360.L ft.
' $2240/L ft.
; $3330/L ft.
30 HP/ 40 KW ($2.00/hr)
50 HP/ 67 KW ($3.35/hr)
100 HP/134 KW ($6.70/hr)
I NOTES: (1) Bas.ed on manufacturers replies to Project questionnaire, equipment costs only.
(2) Based on Port Authority Engineering Department estimates, assuming favorable site conditions.
{3) TRAX based on estimate for BOEING; DEAN based on estimate for APL.
(4) Energy cost based on $.05 per kilowatt hour.
* Dunlop and RATP assume$ conversion rate at mid '77.
i J
BOEING
\ (two direction) j : $ 690,000
; $ 950,000
i $1,600,000
$1430/L ft.
$2650/l ft.
: $4020/L ft.
50 HP/ 67 KW ($2.50/hr)
I 70 HP/ 44 KW ($4.75/hr) I I 120 HP/160 KW ($8.00/hr) '
TABLE 3.3
11EAN RFSEARCH
(one direction)
$ 600,000
$ 875,000
$1,500,000
! Note (3)
$1360/L ft.
$2240/L ft.
$3330/L ft.
N.A.
3.4 Developer Qualifications
A factor determining the prospective supp1ier of a variable
speed accelerating moving walkway system for a public demonstration
will be the qualifications of the supplier to manufacture and install
the AMWS according to project specifications, costs and schedules, and
to provide technical and logistical support for the public use demon
stration. A positive feature of moving way systems, including variable
speed accelerating moving walkways, are their basic mechanical simpli
city. This will simplify field installation problems, system shakedown,
and maintenance. If necessary, well established mechanical engineering
consultants are available to assist AMWS developers having limited ex
perience with local construction, institutional and labor practices.
The Dunlop Corporation, developer of the Speedaway system
is qualified to manufacture a demonstration unit and to provide the
necessary technical and logistic support because of its extensive ex
perience as a manufacturer of conventional escalators and moving walks
in Europe. Furthermore, the manufacturer has operated prototype and
near production units in its factory, gaining valuable experience in
system production and maintenance. Dunlop could encounter minor dif
ficulties because of inexperience with U.S. construction practices, but
this problem is not considered significant.
The Regie Autonome de Transports Parisiens (RATP), developer
of the TRAX system, is a transportation authority with extensive ex
perience as an owner-operator of conventional escalators and moving
walks, but no direct capabilities to manufacture and support the demon
stration. RATP has retained a consultant specializing in locating
- 64 -
United States firms as licensee manufacturers of foreign products, so
that it can be anticipated that a qualified supplier can be found for
the TRAX system. RATP running experience with the TRAX system, plus
its experience with its own conventional walkway systems provides a
good technical background for the demonstration support task.
Johns Hopkins University, Applied Physics Laboratory, devel
opers of the 11APL 11 system have a well-established reputation for tech
n1ca1 competence in research and development, but no capabilities to
manufacture a demonstration AMWS system, nor to supply maintenance
support. The University would require a manufacturer to produce a
demonstration unit and provide the necessary logistic support. A
licensee agreement with an established escalator or moving walk manu
facturer, or other similar agreement, could probably satisfy the sup
plier qualifications requirement.
The Boeing Corporation has a well established reputation in
aerospace and transportation system research, development, manufactur
ing, and installations, but no direct experience with moving way system
manufacturing and installation. As noted previously, installation ex
perience is not considered to be a critical factor because of system
simplicity and the availability of competent consultants and contractors
in this area.
The Dean Research Corporation, developers of the roller system,
have experience with the manufacturing and installation of industrial
conveyors, but no known experience with the construction trades and
jurisdictions normally involved in escalator and moving walk installation.
- 65 -
This is not an insuperable qualifications factor, but would require
assurance of adequate financial backing for a venture of this magnitude
and duration.
- 66 -
3.5 Safety and Human Factors
The safety and human f~ctors of variable speed moving walkways
has been developed in detail in the c Report of the 'Project series -
11Acceleratjng Maying Walkway Systems - Safety and Hyman factors 11• The
report concluded that based on an overview of transportation safety, an
identification and evaluation of possible AMWS hazards, an analysis of
moving way accident experience on conventional escalators, the reports
of safety consultants retained 1s part of Project, as well as the re
sult of a special Project Safety Seminar, that there appeared to be no
reason, apriori, why an AMWS cannot be operated in a public demonstra
tion mode at acceptable levels of safety. The conclusions of the re
port were founded on the assumption that a basic safety program is fol
lowed for the public use demonstration addressing human factors charac
teristics and equipment design, equipment operation and maintenance,
prior instruction of passengers in correct use, the demonstration
environment is appropriate and controls are maintained that assure pro
per use of the system.
The c Report developed six potential accident risk categories
that are associated with the operation and use of accelerating walkways.
These risk categories have been termed (1) inertial, (2) entrapment,
(3) divergence and surface discontinuity, (4) bunching, (5) post prob
lems, and (6) mechanical failure. An additional potential risk would
be individual physiological or psychological responses to the 'equipment
movement, possibly in combination with characteristics of the environ
ment, equipment finishes, and lighting, motion and stroboscopic illusions,
- 67 -
or other similar disorienting effects.
The inertial hazard refers to the movement forces places on
the user by the acceleration, deceleration, the rate of changes these
factors, and emergency stopping. Coriolis is another motion affect,
not associated with the candidate systems, but present in systems
using turntables or other devices involving circular movement paths to
accelerate or decelerate passengers. Too rapid acceleration or decel
eration could cause AMWS passengers to lose their footing and fall,
unless the fall is arrested by grasping a handrail.
The entrapment hazard is common to all moving machinery and
involves the catching and possible ingestion into the equipment of
clothing, footwear, or human extremities. Possible entrapment hazards
with the systems reviewed in the assessment will exist at combplates
and other types of transitional surfaces similar to those of existing
conventional walkways. Additional entrapment potential may also exist
at the intermeshing treadway surfaces characteristic of the APL, TRAX
and Boeing systems, and where the smooth triangular pallet surface edges
retreat beneath the stationary balustrade in the deceleration section of
the Dunlop Speedaway. AMWS handrails may also offer possibilities for
entrapment as they converge in deceleration sections or where hand grip
designs have features that might catch clothing or purse straps, or where
the handrail return configuration, at the point where the handrail enters
the balustrade, is improperly designed or located.
Divergence is defined as a displacement or differential in tread
way or handrail speed or direction. Discontinuities are interruptions in
- 68 -
treadway or handrail surfaces. Examples of divergence and discontinuity
problems on conventional escalators and moving walkways exist at the
entry and exits where it becomes necessary for the user to adjust to
differentials between stationary pavement surfaces and the equipment 1 s
moving treadway and handrail. The escalator presents another divergence
and discontinuity problem with its emerging stepped risers, causing the
upsetting of riders who stand on the line between two treads as they
shift into the stepped stairway configuration. Several divergence and
discontinuity situations have been identified on the systems under re
view in this report. Some systems are not sufficiently developed, or
have components that are not yet developed for meaningful comparisons.
The Dunlop Speedaway system will require adjusting hand positions for
its sequence of seven handrails as well as for a differential in the
handrail speed relative to the treadway. Shifting treadway positions,
or more accurately the shift in the facing direction of the rider rela
tive to the direction of movement on the system, may also disorient
some users of the Speedaway. Expanding and contracting handrails and
treadway surface configurations on other systems will also create dif
ferentials between hand location relative to standing position, requir
ing adjustment of user hand and/or body positions.
Divergence and discontinuity situations are mainly an acci
dent hazard for inattentive users, those under the influence of alco
hol or drugs, or segments of the elderly and handicapped with impaired
perception and reaction capabilities. Persons with obscured views of
handrail or treadway surfaces due to dense pedestrian traffic or hand
- 69 -
carried packages may also experience some difficulty adjusting to
divergence and discontinuity situations.
Bunching may be defined as the crowding of pedestrians to
such an extent that their free movement is restricted. Bunching is
considered to be a potential hazard on Accelerating Walkways because
of the treadway contraction and reduction of surface area in the decel
eration section of these systems. Under certain pedestrian traffic con
ditions, bunching could cause a dangerous jamming or pile up. The
bunching problem exists on the TRAX1 APL and Boeing systems because of
the 5:1 contraction of the treadway surface in their deceleration sec
tions. Bunching also occurs to a limited and less critical degree on
the Speedaway in the deceleration section where pallet ends move be
neath the balustrade. The Dean roller system is not considerd to pre
sent a bunching problem because the treadway surface does not contract.
User education, visual and audial warnings, more formalized indications
of correct standing positions, and other control strategies will be re
quired to minimize the prospects of bunching on accelerating walkway
systems with high ratios of treadway contraction.
The post problem can be described as the presence of any sta
tionary object or design feature along the system or at its outlet which
protrudes into the walkway plane from the sides, or from above, situated
in such a way that it could come in contact with moving passengers.
Protruding moldings or other irregularities in the balustrade surface
can cause post situations by catching packages, shopping carts, etc.
and thereby impacting the rider and possibly throwing him off balance.
Serious post problems have not been identified with the system reviewed
- 70 -
in the assessment as currently existing, but as these systems advance
from the relatively unfinished prototype stage, design features such
as balustrade configurations will have to be carefully reviewed to
determine if post hazards exist.
Mechanical failure risks occur where components of a system
fail in a manner hazardous to passengers. As pa.rt of the design devel-
opment, manufacture and testing, and procurement phases of the Project,
the potential failure modes of each element of candidate systems will
require identification, and the potential consequences of this failure
on rider safety evaluated.
A preliminary sullll1ary of hazard categories for the five sys
tems under consideration, in this report, based on the amount of equip
ment details available as of the date of the report, is contained on
Table 3.4 following.
- 71 -
.._, N
SYSTEM INERTIAL
··---+-----
\)lJNLOP '3PEEDAWAY
TRAX
APL
i Design objective is to meet motion criteria. Handrail oroximity is factor at entry and exit.
Design obJective is to meet motion criteria.
Same as above.
ENTRAPMENT
A_MWS EQUIPMENl HAZARD SUMMARY
rl A Z A R D C A T E G O R Y -------·------]
DIVERGENCE BUNCHING POST PROBLEM ----+-----·------'------···~-·~·-
! I
Equipment tolerances standard, conventional combing at ends, shearing concern for pallet beneath balustrade at deceleration section, multiple handrail de-tailing may increase I entrapment probabi 1 i ty .I
Segmented handrail/ I Minor, minimized by ex-iHandrail transition I treadway speed differ- I pended area decelera- 1detailing is stationar~ entials transverse t t1on section. i feature. I displacement adjacent ! 1
treads. 1 I
I -+----
Conventionai ·:ombing a Synchronicity of handends and at interrnesh- rai I and treadway exIng treadway, surfaces pansion and contrachandrail detail in,i not tion. sufficiently developed
D1,crease in treadway dtea in deceleration zc,ne proportioned to s,,eed ratio.
·------t- --·-·-····· -·-·-•·-··-· Same as above, plus rotative action of leaves during acr.e1. and decel. may entrap.
Synchronicity of hand- ! S,me as above. r~il and treadway ex-pansion ana contrac-tion .
Not identified. plete equipment ing unknown.
Sallle as above.
Comdetail ~
MECHANICAL
No abnormal hazard identifiP.d, missing pallet protection desirable.
No abnormal hazard identified, missing pallet orotection desirable.
Same as above.
TABLE 3.4
Multiple handrail grasp and release, handra!l proximity, transverse movement treads, hand-
. rail and tread speed · differences
Expanding, contracting handrail and treadways wi 11 require foot and hand position dajustments.
Same as above.
----·--·-------•--..----- --------+---·-·--·-·-- -~---------· ----·~-·-·--------BOEING
JEAN RE~EARCH
Same as above.
Same dS above.
·········-- ----·-------
, Same as TRAX. Same as TRAX S, me as above. Same as above. Same as above. iame 11s above. ---4------------ ----4- -- -·-·· -·-----··
Combing detail unknown Treadway does not ro 11 ers are of torque contract, speed ,ji f-1 imit design, paten- ferential adjacent tially reducing entrap rollers. Handrail ment hazard. Handrail confiouration not deta 11 i ng unknown. defined. Rollers may build up friction coating film in use increasing en-trapment.
i Treadway does not ccntract, dif-ferential rollers will potentially ccntribute to some bL.nching.
-------------·--·-·----· ~ -·------
' Same as above. 1,0 l l er seizure cou 1 d Handra I I confi qura ti on cause tripping hazard. ' not defined.
A P P E N D I X
APPENDIX
REFERENCED BIBLIOGRAPHY
1. "American National Standard Safety Code for Eleva.tors, Dumbwaiters, Escalators and Moving Walks - ANSI - Al7.1'1
1 pub. Amer. Soc. Mech. Engrs. N.Y., N.Y., 337 pp., 1971 with Rev. - recommended national safety code for escalator and moving walk design, operation.
2. Fruin, John J. 206 pp. systems, queuing,
-11 Pedestrian Planning and Design 11
- MAUDEP 1971, Planning and design objectives, procedures, pedestrian data ·pedestrian characteristics walkways stairways, time-motion study data escalator utilization.
3. J. Tough and C. 0 1 Flaherty - "Passenger Conveyors 11 - pub. Ian Allan
1971, 176 pp. Comprehensive review history and development of moving way transportation systems, discusses AMWS concepts, lists moving walk installations.
4. Walbridge, E. W. - 11Multilane Passenger Conveyors" - ASCE Trans. Eng. Journ., Aug. 1 75, pp. 463-477, bib. Discusses characteristics, possible applications, and problems associated with multiple array of conventional moving walks operating at different speeds.
5. Jackson and Moreland (Inc.) - 11 Feasibility of Moving Walks/Boston -Report B, Engineering 11
, Jan. 1 71, 209 pp. p 1 us appendices. Detailed discussion of many aspects of moving walk development including human factors, safety, equipment design, maintenance, costs, problem areas, contains literature and patent search summary, annotated bibliography.
6. Elms, Charles P. (edit.) - "Moving Way Transit 11 - Lea Transit
Compendium, Vol. 1, No. 2, 1974, 52 pp. Summary review of moving way technology giving available engineering data, status of system development, system description.
7. Todd, J. K. - 11 The Dunlop Speedaway - A High Speed Passenger Conveyor11 - Intersociety Conf. on Transportation, July 1 76, 8 pp. Problem of large volume movement over relatively short distances has not been addressed, speed present moving walks too slow, discusses combing, post problems in line AMWS, describes Speedaway system, evaluates benefits.
8. Mehmi, A., Ayers, K. B. - "Design of High Speed Moving Pavements for Mass Transit" - TT 7410, Loughborough University of Technology, Oct. 1 74, 139 pp. Summary of characteristics of various proposed AMWS systems, including disadvantages; proposed development of a system using sliding lenticular pallets, similar to Speedaway system; recommended acceleration/deceleration rates 1.77 ft/s2; computer designed tread geometry.
- A-1 -
APPENDIX
9. Blevins, R. w. (et ~l) - 11 V~riable Speed Walkways" - Elevator World, May 1 76, pp. 25-99. Description, data Johns Hopkins, APL AMWS.
- A-2 -
APPENDIX
CHRONOLOGICAL HIGHLIGHTS
VARIABLE SPEED CONTlNUOUSLY MQYING WALK DEVELOPMENT
1874 U.S.A., Speer's Moving Pavement Proposal for N.Y.C., 20 km/hr
moving platform propelled by steam driven wheels riding on a
track. Boarding and leaving from six seat trolleys running
parallel and adjacent to moving platform using friction drive
to platform.
1887 U.S.A., Pearson's Concentric Ring Platforms proposed to use a
number of large concentric platforms turning in same direction
but at differential speed. Slowest platform in center, outer
platform fastest and used to board contiguous train running at
matching speed.
1888 Germany, Rettig's Stepped Train Patent, several parallel and
adjacent moving platforms running at 5.3, 10.8 and 16.2 km/hr
with passengers stepping from one platform to the next. Hand
posts fitted to slower platforms, seats to fastest platform.
Platforms ran on wheels on tracks with cable propulsion.
*1893 U.S.A., Silsbee and Schmidt, Chicago Moving Platform for 1893
World's Columbian Exposition - Two contiguous platforms opera
ting at 3 mph and 6 mph. Elliptical layout 1310 meters long.
Wheels of slow platform ran on rails and electrically powered.
Fast platform mounted on rails which were propelled from the
top of the slow platform wheels giving a 2/1 speed differen
tial. Capacity 31,680 pass./hour.
- A-3 -
*1896
1896
APPENDIX
Berlin, Moving Platforms, similar to 1893 Chicago installation,
460 meter system dumb~bell shaped.
France, le Boul's Rotating Pier, proposed 30 meter diameter
rotating platfonn, open at center where passengers entered by
stairway, and transferred at the circumference to a continuously
moving chain of trucks carrying seats. Principle eventually
used in 1964 Swiss National Exhibition for Telecanape Railway.
1898 Gennany, Vietors' Epicycloidal Railway. Loading disc rotated
*1900
between stationary central circular platform and a moving annu
lar platfonn.
France, Blot/Guyenet/de Mocomble 1900 Paris Exposition, 3.3 km
long, with endless chain of flat trucks operating on two paral
lel and adjacent tracks at speeds of 3.6 km/hr and 7.2 km/hr
respectively. Electrically powered. Carried 6.694 million
passengers.
1904 U.S.A., 34th Street, N.Y.C. proposal for four platform system
ml923
moving at O, 3, 6 and 9 mph in parallel arrangement with capa
city of 48,000 pass/hr. Proposed from 1st Avenue to 9th Avenue.
Opposed by Metro Street Railway Co. Platforms rode on wheels on
tracks, electrically powered.
U.S.A., Putnam's N.Y.C. 42nd Street Proposal for end looped
subway system from 3rd Avenue to 8th Avenue to replace subway
shuttle service. Parallel platforms moving at 3, 6 and 9 mph.
Seats on fastest platform. Powered by linear induction motors
(LIM). Capacity 35,640 pass/hr. Elliptical demonstration
system built and operated in Jersey City.
A-4 -
APPENDIX
1924 France, Cfty of Paris, proposal in competition for new system
to supplement Metro. Ten mph continuously running platform
(with seats) boarded from interlocking cascade of belts, which
accelerated from l 1/2 to 10 mph. Pull scale tests indicated
accelerating/decelerating sections would be each 30 ft. long
for standing passengers, resulting stations were too long,
therefore not installed.
1935 U.S.A., Storer/Westinghouse Bi-Way System of two parallel moving
platforms. Local platform accelerated from zero to 24 km/hr
at which speed it matches speed of express platform. Proposal
only.
1956 U.S.A., Pfeiffer's cascade of stretchable rubber belts proposal
to provide acceleration/deceleration ability.
1964 U.S.A., Bell Synchroveyor. Loop within loop conveyors. Inner
loops are variable speed, outer loops constant speed. Transfers
made at synchronous speed. Proposal only, electro-mechanically
driven.
11964 Switzerland, Bouladon/Batelle Continuous Integrator. Transverse
entry/exit at safe speed combined with longitudinal acceleration
and deceleration to provide 3/1 to 5/1 variable speed ratio con
veyance of standing passengers. Basis of subsequent 1 Speedaway 1
system development by Dunlop in England.
1966 U.S.A., Ayres & McKenna Veriflex deformable diamond mesh walk to
provide 5/l to 6/1 speed variation. Mesh belting roller suppor
ted at edges and propelled by electrically powered cable, chains
or screws. In model form only.
- A-5 -
4)1969
APPENDIX
U.S.A., Blevins/A.P.L. Variable Speed Walkway, 3/1 to 5/1 speed
ratio, Variable geometry overlapping comb leaves, chain linked
and operating on variable pitch electrically driven screws.
Leaves run on rollers in supporting tracks. Ten meter lab. demo
completed.
1969 U.K .• Turner's lenticular Accelerator, in which lenticular shaped
(convex and concave) platforms are employed 1n a similar manner
to Bouladon system except it has the ability to change direction
without speed change and vice versa.
1970 France, Engins-Matra Tras. 18. Endless belt of rods forming de
fonnable diamond mesh covered with bed of overlapping metal plates.
5/1 speed ratio. Electrically driven. Mock-ups, models and small
moving section built.
1970 France, RAPT TRAX. Endless loop system of comb and groove plates
which shorten and lengthen to provide 4/l speed ratio. Electrical
ly driven with chains, gears and links, 70 meter prototype test/
demo unit under development.
197? Germany, Krauss-Maffei Transurban Conveyor comprising inner disc
at ground level serving as rotary lift to inside of rotating disc.
Passengers move to perimeter to transfer to a constant speed (13
km/hr) walkway. Concept and model.
1971. U.S.A., Georgia Institute of Technology Accelerating Belt.
Student project proposal for Downtown Atlanta Radial Study.
Overlapping plates linked together. Overlap increases as
speed increases. Electrically driven with hydraulic damper
linkage.
- A-6
APPENDIX
1971 U.K., Cranfield lnstitute of Technology, Travelling Wave Walk.
Flexible tube nipped by roller to form seal. When tube inflated
pressure exerted on roller propels it along the tube. Concept
and modelling.
1973 U.K., NRDC Scimitar Pavement. Scimitar shaped, tapered and
curved pallets similar to 1Speedaway 1 concept except that it
can negotiate curves.
1975 U.K., Mann's Crestwalk passenger conveyor of overlapping pallets
supported and guided by tracked rollers and propelled by LIM
which imparts acceleration, high speed and deceleration cycles
to pallets and which gives small phase difference in the cycles
between adjacent pallets. The result is to produce areas of
increased speed. If the passenger walks forward he will remain
on a speed crest. If the passenger stops walking, he will reach
safe alighting speed. Concept only.
? U.S.A., Candella Variable Speed Belt is an accel ./decel. moving
belt where the effective belt length varies, increasing as speed
increases and vice versa. The belt is wrapped over sets of rods
which ride on end rollers in side tracks to accomplish this.
Concept only.
? U.S.A., Jackson and Moreland Oscillating Elastic Apron Proposal.
*Built and operated in public
IDemonstration unit built and operated.
- A-7 -